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cuberite-2a/src/WorldStorage/SchematicFileSerializer.cpp
2015-01-23 10:03:39 +01:00

308 lines
8.1 KiB
C++

// SchematicFileSerializer.cpp
// Implements the cSchematicFileSerializer class representing the interface to load and save cBlockArea to a .schematic file
#include "Globals.h"
#include "OSSupport/GZipFile.h"
#include "FastNBT.h"
#include "SchematicFileSerializer.h"
#include "../StringCompression.h"
#ifdef SELF_TEST
static class cSchematicStringSelfTest
{
public:
cSchematicStringSelfTest(void)
{
cBlockArea ba;
ba.Create(21, 256, 21);
ba.RelLine(0, 0, 0, 9, 8, 7, cBlockArea::baTypes | cBlockArea::baMetas, E_BLOCK_WOODEN_STAIRS, 1);
AString Schematic;
if (!cSchematicFileSerializer::SaveToSchematicString(ba, Schematic))
{
assert_test(!"Schematic failed to save!");
}
cBlockArea ba2;
if (!cSchematicFileSerializer::LoadFromSchematicString(ba2, Schematic))
{
assert_test(!"Schematic failed to load!");
}
}
} g_SelfTest;
#endif
////////////////////////////////////////////////////////////////////////////////
// cSchematicFileSerializer:
bool cSchematicFileSerializer::LoadFromSchematicFile(cBlockArea & a_BlockArea, const AString & a_FileName)
{
// Un-GZip the contents:
AString Contents;
cGZipFile File;
if (!File.Open(a_FileName, cGZipFile::fmRead))
{
LOG("Cannot open the schematic file \"%s\".", a_FileName.c_str());
return false;
}
int NumBytesRead = File.ReadRestOfFile(Contents);
if (NumBytesRead < 0)
{
LOG("Cannot read GZipped data in the schematic file \"%s\", error %d", a_FileName.c_str(), NumBytesRead);
return false;
}
File.Close();
// Parse the NBT:
cParsedNBT NBT(Contents.data(), Contents.size());
if (!NBT.IsValid())
{
LOG("Cannot parse the NBT in the schematic file \"%s\".", a_FileName.c_str());
return false;
}
return LoadFromSchematicNBT(a_BlockArea, NBT);
}
bool cSchematicFileSerializer::LoadFromSchematicString(cBlockArea & a_BlockArea, const AString & a_SchematicData)
{
// Uncompress the data:
AString UngzippedData;
if (UncompressStringGZIP(a_SchematicData.data(), a_SchematicData.size(), UngzippedData) != Z_OK)
{
LOG("%s: Cannot unGZip the schematic data.", __FUNCTION__);
return false;
}
// Parse the NBT:
cParsedNBT NBT(UngzippedData.data(), UngzippedData.size());
if (!NBT.IsValid())
{
LOG("%s: Cannot parse the NBT in the schematic data.", __FUNCTION__);
return false;
}
return LoadFromSchematicNBT(a_BlockArea, NBT);
}
bool cSchematicFileSerializer::SaveToSchematicFile(const cBlockArea & a_BlockArea, const AString & a_FileName)
{
// Serialize into NBT data:
AString NBT = SaveToSchematicNBT(a_BlockArea);
if (NBT.empty())
{
LOG("%s: Cannot serialize the area into an NBT representation for file \"%s\".", __FUNCTION__, a_FileName.c_str());
return false;
}
// Save to file
cGZipFile File;
if (!File.Open(a_FileName, cGZipFile::fmWrite))
{
LOG("%s: Cannot open file \"%s\" for writing.", __FUNCTION__, a_FileName.c_str());
return false;
}
if (!File.Write(NBT))
{
LOG("%s: Cannot write data to file \"%s\".", __FUNCTION__, a_FileName.c_str());
return false;
}
return true;
}
bool cSchematicFileSerializer::SaveToSchematicString(const cBlockArea & a_BlockArea, AString & a_Out)
{
// Serialize into NBT data:
AString NBT = SaveToSchematicNBT(a_BlockArea);
if (NBT.empty())
{
LOG("%s: Cannot serialize the area into an NBT representation.", __FUNCTION__);
return false;
}
// Gzip the data:
int res = CompressStringGZIP(NBT.data(), NBT.size(), a_Out);
if (res != Z_OK)
{
LOG("%s: Cannot Gzip the area data NBT representation: %d", __FUNCTION__, res);
return false;
}
return true;
}
bool cSchematicFileSerializer::LoadFromSchematicNBT(cBlockArea & a_BlockArea, cParsedNBT & a_NBT)
{
int TMaterials = a_NBT.FindChildByName(a_NBT.GetRoot(), "Materials");
if ((TMaterials > 0) && (a_NBT.GetType(TMaterials) == TAG_String))
{
AString Materials = a_NBT.GetString(TMaterials);
if (Materials.compare("Alpha") != 0)
{
LOG("Materials tag is present and \"%s\" instead of \"Alpha\". Possibly a wrong-format schematic file.", Materials.c_str());
return false;
}
}
int TSizeX = a_NBT.FindChildByName(a_NBT.GetRoot(), "Width");
int TSizeY = a_NBT.FindChildByName(a_NBT.GetRoot(), "Height");
int TSizeZ = a_NBT.FindChildByName(a_NBT.GetRoot(), "Length");
if (
(TSizeX < 0) || (TSizeY < 0) || (TSizeZ < 0) ||
(a_NBT.GetType(TSizeX) != TAG_Short) ||
(a_NBT.GetType(TSizeY) != TAG_Short) ||
(a_NBT.GetType(TSizeZ) != TAG_Short)
)
{
LOG("Dimensions are missing from the schematic file (%d, %d, %d), (%d, %d, %d)",
TSizeX, TSizeY, TSizeZ,
(TSizeX >= 0) ? a_NBT.GetType(TSizeX) : -1,
(TSizeY >= 0) ? a_NBT.GetType(TSizeY) : -1,
(TSizeZ >= 0) ? a_NBT.GetType(TSizeZ) : -1
);
return false;
}
int SizeX = a_NBT.GetShort(TSizeX);
int SizeY = a_NBT.GetShort(TSizeY);
int SizeZ = a_NBT.GetShort(TSizeZ);
if ((SizeX < 1) || (SizeX > 65535) || (SizeY < 1) || (SizeY > 256) || (SizeZ < 1) || (SizeZ > 65535))
{
LOG("Dimensions are invalid in the schematic file: %d, %d, %d", SizeX, SizeY, SizeZ);
return false;
}
int TBlockTypes = a_NBT.FindChildByName(a_NBT.GetRoot(), "Blocks");
int TBlockMetas = a_NBT.FindChildByName(a_NBT.GetRoot(), "Data");
if ((TBlockTypes < 0) || (a_NBT.GetType(TBlockTypes) != TAG_ByteArray))
{
LOG("BlockTypes are invalid in the schematic file: %d", TBlockTypes);
return false;
}
bool AreMetasPresent = (TBlockMetas > 0) && (a_NBT.GetType(TBlockMetas) == TAG_ByteArray);
a_BlockArea.Clear();
a_BlockArea.SetSize(SizeX, SizeY, SizeZ, AreMetasPresent ? (cBlockArea::baTypes | cBlockArea::baMetas) : cBlockArea::baTypes);
int TOffsetX = a_NBT.FindChildByName(a_NBT.GetRoot(), "WEOffsetX");
int TOffsetY = a_NBT.FindChildByName(a_NBT.GetRoot(), "WEOffsetY");
int TOffsetZ = a_NBT.FindChildByName(a_NBT.GetRoot(), "WEOffsetZ");
if (
(TOffsetX < 0) || (TOffsetY < 0) || (TOffsetZ < 0) ||
(a_NBT.GetType(TOffsetX) != TAG_Int) ||
(a_NBT.GetType(TOffsetY) != TAG_Int) ||
(a_NBT.GetType(TOffsetZ) != TAG_Int)
)
{
// Not every schematic file has an offset, so we shoudn't give a warn message.
a_BlockArea.SetWEOffset(0, 0, 0);
}
else
{
a_BlockArea.SetWEOffset(a_NBT.GetInt(TOffsetX), a_NBT.GetInt(TOffsetY), a_NBT.GetInt(TOffsetZ));
}
// Copy the block types and metas:
size_t NumBytes = a_BlockArea.GetBlockCount();
if (a_NBT.GetDataLength(TBlockTypes) < NumBytes)
{
LOG("BlockTypes truncated in the schematic file (exp %d, got %d bytes). Loading partial.",
(int)NumBytes, (int)a_NBT.GetDataLength(TBlockTypes)
);
NumBytes = a_NBT.GetDataLength(TBlockTypes);
}
memcpy(a_BlockArea.m_BlockTypes, a_NBT.GetData(TBlockTypes), NumBytes);
if (AreMetasPresent)
{
size_t NumBytes = a_BlockArea.GetBlockCount();
if (a_NBT.GetDataLength(TBlockMetas) < NumBytes)
{
LOG("BlockMetas truncated in the schematic file (exp %d, got %d bytes). Loading partial.",
(int)NumBytes, (int)a_NBT.GetDataLength(TBlockMetas)
);
NumBytes = a_NBT.GetDataLength(TBlockMetas);
}
memcpy(a_BlockArea.m_BlockMetas, a_NBT.GetData(TBlockMetas), NumBytes);
}
return true;
}
AString cSchematicFileSerializer::SaveToSchematicNBT(const cBlockArea & a_BlockArea)
{
cFastNBTWriter Writer("Schematic");
Writer.AddShort("Width", a_BlockArea.m_Size.x);
Writer.AddShort("Height", a_BlockArea.m_Size.y);
Writer.AddShort("Length", a_BlockArea.m_Size.z);
Writer.AddString("Materials", "Alpha");
if (a_BlockArea.HasBlockTypes())
{
Writer.AddByteArray("Blocks", (const char *)a_BlockArea.m_BlockTypes, a_BlockArea.GetBlockCount());
}
else
{
AString Dummy(a_BlockArea.GetBlockCount(), 0);
Writer.AddByteArray("Blocks", Dummy.data(), Dummy.size());
}
if (a_BlockArea.HasBlockMetas())
{
Writer.AddByteArray("Data", (const char *)a_BlockArea.m_BlockMetas, a_BlockArea.GetBlockCount());
}
else
{
AString Dummy(a_BlockArea.GetBlockCount(), 0);
Writer.AddByteArray("Data", Dummy.data(), Dummy.size());
}
Writer.AddInt("WEOffsetX", a_BlockArea.m_WEOffset.x);
Writer.AddInt("WEOffsetY", a_BlockArea.m_WEOffset.y);
Writer.AddInt("WEOffsetZ", a_BlockArea.m_WEOffset.z);
// TODO: Save entities and block entities
Writer.BeginList("Entities", TAG_Compound);
Writer.EndList();
Writer.BeginList("TileEntities", TAG_Compound);
Writer.EndList();
Writer.Finish();
return Writer.GetResult();
}